A mutant of Mycoplasma mycoides subsp. mycoides lacking the H2O2-producing enzyme l-α-glycerophosphate oxidase

A universal rapid procedure to determine the DNA base composition (mol% guanine + cytosine) of Gram-positive bacteria is described. Cells of Gram-positive bacteria were lysed with achromo-peptidase and the mol% G + C of their DNAs were determined by using high performance liquid chromatography. One ml of a Gram-positive bacterial suspension which matched MacFarland No. 3 standard turbidity was sufficient to determine the mol% G + C within 3 h.     

Rapid GC mol% screening of primary culture lysates using horizontal slab gel electrophoresis

An electrophoretic technique for the rapid screening of GC mol% of bacterial DNA was modified and evaluated. Modifications of the technique included its adaptation to horizontal slab electrophoresis. Primary culture lysates (one per gel) of bacterial strains with unknown ratios of G+C/A+T+G+C (GC mol%), and reference strains whose GC mol% had been determined by thermal denaturation, were simultaneously electrophoresed for 2 h in polyacrylamide-agarose gels and mobilites of the chromosomal DNA bands were compared with the GC mol% values obtained from thermal denaturation curves. Results indicated a positive correlation (r = 0.80, df = 23) between GC mol% and electrophoretic mobility. The procedure, as modified, requires a minimum of equipment and resources and allows for the determination of GC mol% values with sufficient accuracy to serve as a means for inexpensive and routine screening of bacterial isolates.     

DNA base composition of Rickettsia tsutsugamushi determined by reversed-phase high-performance liquid chromatography

The DNA base composition of Rickettsia tsutsugamushi was determined by reversed-phase high-performance liquid chromatography and compared with that of Rickettsia rickettsii. The G+C contents were 28.1 to 30.5 mol% for R. tsutsugamushi and 32.1 mol% for R. rickettsii.     

QUANTUM AND CONTINUOUS EVOLUTION OF DNA BASE COMPOSITION IN THE YEAST GENUS PICHIA

This paper investigates the noncontinuous nature and evolution of the base composition of nuclear DNA (expressed as mol% guanine + cytosine) in species of the yeast genus Pichia (sensu Kurtzman, 1984b). The pattern of change in the G + C contents in species of this genus, which range from about 27 to 52 mol%, was evaluated. When specifically those species of Pichia were analyzed that have evolved in necroses of cactus species and associated Drosophila, a periodic change in the G + C contents of approximately 3.0–3.2 mol% was detected by a “bootstrapping” method, Fourier analysis, and a nonlinear trigonometric model. Pichia species occurring in exudates of broad-leaved deciduous trees or associated Drosophila and substrates such as soil and water (“other”) showed a periodicity of 2.5–2.6 mol%, whereas species associated with conifers and associated bark beetles showed no significant periodicity. Periodicity in the most recent association (cactus and resident Drosophila) as compared to the lack of periodicity in the oldest association (conifer-beetle) may indicate mixed evolutionary processes. Low mol% G + C values appear more frequently in the relatively recent cactus and Drosophila-associated yeast species. In addition, low mol% G + C species do not display the ancestral bud-meiosis mode of sexual reproduction which occurs frequently in medium to high mol% G + C yeasts. It was found that the mol% G + C content of the Drosophila- and cactus-associated Pichia species is positively correlated with the number of compounds fermented or respired by these yeast species. Possible reasons for the periodic changes in mol% G + C content accompanying speciation include aneuploidy, allopolyploidy, the presence of nuclear plasmids, and regular differences in moderately repetitive portions of DNA. Since significant DNA complementarity is virtually limited to species within a relatively narrow G + C group, this suggests that there are at least two processes which alter the G + C content between species, one saltational and one continuous.     

Taxonomy of alkaliphilic Bacillus strains

The DNA base compositions of 78 alkaliphilic Bacillus strains were determined. These strains were grouped as follows: DNA group A, guanine-plus-cytosine (G+C) content of 34.0 to 37.5 mol% (17 strains); DNA group B, G+C content of 38.2 to 40.8 mol% (33 strains); and DNA group C, G+C content of 42.1 to 43.9 mol% (28 strains). DNA group A includes the type strain of Bacillus alcalophilus Vedder 1934. DNA-DNA hybridization studies with DNA group A strains revealed that only one strain, strain DSM 2526, exhibited a high level of DNA homology with B. alcalophilus DSM 485T (T = type strain). Neither strain DSM 485T nor any other DNA group A strain is homologous to any of the Bacillus type strains with comparable base compositions. Six strains formed a distinct group containing three highly homologous strains and three strains exhibiting greater than 50% DNA homology.     

Bacillus brevis Migula 1900 taxonomy: reassociation and base composition of DNA.

Of 87 strains previously identified as Bacillus brevis Migula 1900, 58 had G + C contents of 47.0 to 51.9 mol%, a range that included the G + C content (48.7 mol%) of the type strain. The G + C contents for three other groups consisting of 5, 7, and 17 strains were 37.0 to 41.9, 42.0 to 46.9, and 52.0 mol% or higher, respectively. DNA reassociation studies showed that 25 of the 58 strains with G + C contents of 47.0 to 51.9 mol% were closely related genetically to the type strain and to each other. For the most part, this genetically related group was phenotypically homogeneous; variations in the fermentation of mannitol and mannose were observed. My results strongly suggest that many of the strains were misclassified as B. brevis. Consequently, much of the phenotypic heterogeneity of the species B. brevis Migula 1900 is not due to variations exhibited by genetically related organisms, but is the result of variability introduced by the presence of genetically unrelated strains.     

Description of an unusual gram-negative anaerobic rod isolated from periodontal pockets

A Gram-negative rod which grew with an unusual colonial "water-drop" form was isolated from periodontal pocket samples from 12 patients. Six strains were characterized by biochemical tests, cell wall analyses, malate dehydrogenase mobilities, protein profiles, and serology. By these criteria, the organisms formed a group of similar strains which were anaerobic, nonmotile, nonsporing, Gram-negative rods resembling Bacteroides. Comparison of the isolates to American Type Culture Collection strains of Bacteroides showed that they represented a closely related group, distinct from the described species of oral Bacteroides. Initial results on the DNA of the isolates suggested a base ratio of 54-57% G + C. Despite the DNA G + C base ratios currently accepted for the Bacteroides (28-61 mol% G + C), many species fall into a narrower range of 40-52 mol% G + C. This range would exclude the organisms described here and suggests that placing them into the genus Bacteroides may be inappropriate.     

High diversity in DNA of soil bacteria.

Soil bacterium DNA was isolated by minor modifications of previously described methods. After purification on hydroxyapatite and precipitation with cetylpyridinium bromide, the DNA was sheared in a French press to give fragments with an average molecular mass of 420,000 daltons. After repeated hydroxyapatite purification and precipitation with cetylpyridinium bromide, high-pressure liquid chromatography analysis showed the presence of 2.1% RNA or less, whereas 5-methylcytosine made up 2.9% of the total deoxycytidine content. No other unusual bases could be detected. The hyperchromicity was 31 to 36%, and the melting curve in 1 X SSC (0.15 M NaCl plus 0.015 M sodium citrate) corresponded to 58.3 mol% G+C. High-pressure liquid chromatography analysis of two DNA samples gave 58.6 and 60.8 mol% G+C. The heterogeneity of the DNA was determined by reassociation of single-stranded DNA, measured spectrophotometrically. Owing to the high complexity of the DNA, the reassociation had to be carried out in 6 X SSC with 30% dimethyl sulfoxide added. Cuvettes with a 1-mm light path were used, and the A275 was read. DNA concentrations as high as 950 micrograms ml-1 could be used, and the reassociation rate of Escherichia coli DNA was increased about 4.3-fold compared with standard conditions. C0t1/2 values were determined relative to that for E. coli DNA, whereas calf thymus DNA was reassociated for comparison. Our results show that the major part of DNA isolated from the bacterial fraction of soil is very heterogeneous, with a C0t1/2 about 4,600, corresponding to about 4,000 completely different genomes of standard soil bacteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

High diversity in DNA of soil bacteria

Soil bacterium DNA was isolated by minor modifications of previously described methods. After purification on hydroxyapatite and precipitation with cetylpyridinium bromide, the DNA was sheared in a French press to give fragments with an average molecular mass of 420,000 daltons. After repeated hydroxyapatite purification and precipitation with cetylpyridinium bromide, high-pressure liquid chromatography analysis showed the presence of 2.1% RNA or less, whereas 5-methylcytosine made up 2.9% of the total deoxycytidine content. No other unusual bases could be detected. The hyperchromicity was 31 to 36%, and the melting curve in 1 X SSC (0.15 M NaCl plus 0.015 M sodium citrate) corresponded to 58.3 mol% G+C. High-pressure liquid chromatography analysis of two DNA samples gave 58.6 and 60.8 mol% G+C. The heterogeneity of the DNA was determined by reassociation of single-stranded DNA, measured spectrophotometrically. Owing to the high complexity of the DNA, the reassociation had to be carried out in 6 X SSC with 30% dimethyl sulfoxide added. Cuvettes with a 1-mm light path were used, and the A275 was read. DNA concentrations as high as 950 micrograms ml-1 could be used, and the reassociation rate of Escherichia coli DNA was increased about 4.3-fold compared with standard conditions. C0t1/2 values were determined relative to that for E. coli DNA, whereas calf thymus DNA was reassociated for comparison. Our results show that the major part of DNA isolated from the bacterial fraction of soil is very heterogeneous, with a C0t1/2 about 4,600, corresponding to about 4,000 completely different genomes of standard soil bacteria.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization ofAnaplasma marginale DNA

Two procedures were used to isolateAnaplasma marginale bodies from bovine erythrocytes. DNA extracted from bodies prepared by the second method was free of any detectable bovine DNA contamination.Anaplasma marginale DNA was analyzed by agarose gel electrophoresis of endonuclease restriction fragments and by reassociation kinetics. Genome size was estimated to be 340 kb. Base composition of the DNA was 33 mol% guanine+ cytosine (G+C), determined from its thermal denaturation temperature.Anaplasma marginale has a very small genome compared with that of other bacteria and has a low G+C content. It is proposed thatA. marginale may be a close, but degenerate, relative of the rickettsiae.     

Molecular analysis of beta-lactamases from four species of Streptomyces: comparison of amino acid sequences with those of other beta-lactamases

Genes encoding extracellular beta-lactamases of Streptomyces badius, Streptomyces cacaoi, Streptomyces fradiae and Streptomyces lavendulae were cloned and mapped in Streptomyces lividans. DNA sequence analysis of the beta-lactamase genes revealed a high overall G + C content, ranging from 71 to 75 mol%, with a G + C content of 95 mol% at the third position of the codons for all four genes. The primary structure of the beta-lactamases including their signal peptides was deduced. The four beta-lactamases exhibited homology to each other and to class A beta-lactamases from other bacterial genera. We suggest that Streptomyces beta-lactamases are representatives of a superfamily of genes, from which class A beta-lactamases of Gram-negative bacteria may have evolved.     

Differentiation of Gluconacetobacter liquefaciens and Gluconacetobacter xylinus on the basis of DNA base composition,DNA relatedness,and oxidation products from glucose

Gluconacetobacter liquefaciens and Gluconacetobacter xylinus share very similar phenotypic characteristics. They are differentiated by the production of a reddish-brown water-soluble pigment of the former and cellulose production of the latter. However, the loss of the two distinguishing features questions the separate standings of the two species. The DNA base composition and the DNA relatedness of strains of the two species, including other established species of acetic acid bacteria, were determined. G. liquefaciens strains had the higher guanine-plus-cytosine content (G+C content) in DNA, ranging from 63.5 to 66.9 mol%, and G. xylinus had the lower range, from 59.4 to 63.2 mol%. DNA hybridization revealed a low level of DNA similarity between the two species. G. liquefaciens strains produced 2,5-diketogluconic acid and pyrones from glucose, and G. xylinus strains produced 5-ketogluconic acid. From these results, it is unequivocal that G. liquefaciens is a distinct species from G. xylinus.     

Identification and growth of Leuconostoc lactis SHO-54, producing high amounts of NAD-specific 6-phosphogluconate dehydrogenase

The G+C content of the DNA of strain SHO-54 which produces a large amount of NAD-specific 6-phosphogluconate dehydrogenase was 41.0 mol%. The extent of the DNA–DNA homology between this strain and Leuconostoc lactis NRIC 1540 ranged from 72.8% to 95.5%. A minimal medium in which strain SHO-54 grew well was determined, and a high activity of the enzyme (410 nkat/ml) was obtained.     

Molecular analysis of deep-subsurface bacteria

Bacterial isolates from deep-sediment samples from three sites at the Savannah River site, near Aiken, S.C., were studied to determine their microbial community composition and DNA structure by using total DNA hybridization and moles percent G + C. Standard phenotypic identification underestimated the bacterial diversity at the three sites, since isolates with the same phenotype had different DNA structures in terms of moles percent G + C and DNA homology. The G + C content of deep-subsurface bacteria ranged from 20 to 77 mol%. More than 60% of the isolates tested had G + C values similar to those of Pseudomonas spp., and 12% had values similar to those of Acinetobacter spp. No isolates from deeper formations showed the same DNA composition as isolates from upper formations. Total-DNA hybridization and DNA base composition analysis provided a better resolution than phenotypic tests for the understanding of the diversity and structure of deep-subsurface bacterial communities. On the basis of the moles percent G + C values, deep-subsurface isolates tested seemed to belong to the families Pseudomonadaceae and Neisseriaceae, which might reflect a long period of adaptation to the environmental conditions of the deep subsurface.     

Molecular analysis of deep-subsurface bacteria.

Bacterial isolates from deep-sediment samples from three sites at the Savannah River site, near Aiken, S.C., were studied to determine their microbial community composition and DNA structure by using total DNA hybridization and moles percent G + C. Standard phenotypic identification underestimated the bacterial diversity at the three sites, since isolates with the same phenotype had different DNA structures in terms of moles percent G + C and DNA homology. The G + C content of deep-subsurface bacteria ranged from 20 to 77 mol%. More than 60% of the isolates tested had G + C values similar to those of Pseudomonas spp., and 12% had values similar to those of Acinetobacter spp. No isolates from deeper formations showed the same DNA composition as isolates from upper formations. Total-DNA hybridization and DNA base composition analysis provided a better resolution than phenotypic tests for the understanding of the diversity and structure of deep-subsurface bacterial communities. On the basis of the moles percent G + C values, deep-subsurface isolates tested seemed to belong to the families Pseudomonadaceae and Neisseriaceae, which might reflect a long period of adaptation to the environmental conditions of the deep subsurface.     

Identification and growth of Leuconostoc lactis SHO-54, producing high amounts of NAD-specific 6-phosphogluconate dehydrogenase

The G+C content of the DNA of strain SHO-54 which produces a large amount of NAD-specific 6-phosphogluconate dehydrogenase was 41.0 mol%. The extent of the DNA–DNA homology between this strain and Leuconostoc lactis NRIC 1540 ranged from 72.8% to 95.5%. A minimal medium in which strain SHO-54 grew well was determined, and a high activity of the enzyme (410 nkat/ml) was obtained.     

Detection of specificity of a new antigen in Candida tropicalis and its evaluation by taxonomic DNA analyses

Monospecific factor serum for identifying Candida tropicalis was obtained either from rabbit antiserum to heated cells of C. tropicalis M 1519 (S 96) or from antiserum to C. tropicalis IFO 1400, by adsorption with heated cells of Candida albicans serotype A, or C. albicans (A) and Candida krusei, respectively. We designated this adsorbed serum factor t serum. The monospecific factor serum reacted with 31 out of 32 strains of C. tropicalis, only when tested on heat-treated cell antigens, whereas it did not react with any of 72 strains of the six other medically important species of Candida. The morphological and physiological characteristics of the one strain of C. tropicalis that did not react with the factor t serum, designated the t- -strain, were shown to be similar to those of the type strain of C. tropicalis by most of the methods employed for identifying Candida. Therefore, cell wall mannan from the t- -strain was compared with that from several typical strains of C. tropicalis for its specificity by the precipitation reaction and also for its 1H-nuclear magnetic resonance spectrum. The results showed that these mannans are similar to each other serologically and physicochemically, suggesting that the new antigen t is not mannan. Taxonomic characterization of the t-- and several typical strains of C. tropicalis was carried out by determining the mol% G+C of their DNA and also their DNA homology. Although the mol% G+C values of four typical strains of C. tropicalis were fairly similar (35.2 to 36.2 mol% by the Tm method and 35.5 to 36.4 mol% by the HPLC method), the t- -strain had a G+C content of 44.1 (Tm) and 43.3 (HPLC) mol%. Furthermore, the DNAs of the t- -strain and the type strain of C. tropicalis showed only 18.2% relatedness. These results suggest that the antigen corresponding to serum factor t exists only in the cell wall of C. tropicalis strains, not in those of the other medically important Candida, and that the t- -strain should not be classified as C. tropicalis. In conclusion, the taxonomic value and usefulness of factor t serum is primarily for differentiating C. tropicalis from C. albicans serotype A serologically.     

Vibrio neonatus sp. nov. and Vibrio ezurae sp. nov. isolated from the gut of Japanese abalones

Five alginolytic, facultative anaerobic, non-motile bacteria were isolated from the gut of Japanese abalones (Haliotis discus discus, H. diversicolor diversicolor and H. diversicolor aquatilis). Phylogenetic analyses based on 16S rRNA gene and gap gene sequences indicated that these strains are closely related to V. halioticoli. DNA-DNA hybridizations, FAFLP fingerprintings, and phylogenies of gap and 16S rRNA gene sequences showed that the five strains represent two species different from all currently described vibrios. The names Vibrio neonatus sp. nov. (IAM 15060T = LMG 19973T = HDD3-1T; mol% G+C of DNA is 42.1-43.9), and Vibrio ezurae sp. nov. (IAM 15061T = LMG 19970T = HDS1-1T; mol% G+C of DNA is 43.6-44.8) are proposed to encompass these new taxa. The two new species can be differentiated from V. halioticoli on the basis of several features, including beta-galactosidase activity, assimilation of glycerol, D-mannose and D-gluconate.     

Isolation and characterization of a new coccoid methanogen,Methanogenium tatii spec. nov. from a solfataric field on Mount Tatio

A new coccoid methanogen, Methanogenium tatii, was isolated and characterized. The mesophilic isolate can grow on and produce methane from H₂:CO₂ and formate. For growth acetate is strictly required. The cell shape, the G+C content of 54 mol% and DNA-DNA homology data suggest it to be a Methanogenium species.Abbreviations G+C Guanine+Cytosine - SDS Sodium dodecylsulfate